Reversing and speed control for truck motors



NOV. 17, 1953 l M. PERSONS 2,659,851

REVERSING AND SPEED CONTROL FOR TRUCK MOTORS Filed July 30, 1948 8 Sheets-Sheet l Nov. 17, 1953 L. M. PERSONS REVERSING AND SPEED CONTROL FOR TRUCK MOTORS 8 Sheets-Sheet 2 Filed July 50. 1948 Nov. 17, 1953 M. PERSONS 2,659,851

REVERSING AND SPEED CONTROL FOR TRUCK MOTORS Filed July 50 1948 8 Sheets-Sheet 5 97' Ton/JE YS.

Nov. 17, 1953 M. PERSONS REVERSING AND SPEED CONTROL FOR TRUCK MOTORS 8 Sheets-Sheet 4 Filed July 30, 1948 .N0v.-17, 1953 L, M, PERSONS 2,659,851

REVERSING AND SPEED CONTROL FOR TRUCK MOTORS Filed July 30, 1948 8 Sheets-Sheet 5 Nov. 17, 1953 1 M. PERSONS REVERSING AND SPEED CONTROL FOR TRUCK MOTORS 8 Sheets-Sheet 6 Filled July 50, 1948 ar Ark/X 1Q T To RNE )4g Nov. 17, 1953 L. M. PERSONS REVERSING AND SPEED CONTROL FOR TRUCK MOTORS 8 Sheets-Sheet 7 Filed July 50, 1948 Nov. 17, 1953 v l.. M. PERSONS REVERSING AND SPEED CONTROL FOR TRUCK MOTORS s sheets-sheet 8 Filed July 30, 1948 Patented Nov. 17, 1953 UNITED STATES APATENT OFFICE REVERSING AND SPEED CONTROL FOR TRUCK MOTORS Application July 30, 1948, Serial No. 41,695

(Cl. S18- 262) 24 Claims.

The present invention relates to a multi-speed truck control. More particularly, it relates to a control for use with electrically controlled or electrically driven motors, by which the operator may obtain a plurality of speeds, either forward or reverse. There are here illustrated four different speeds, forward and reverse, as well as a neutral position wherein no drive is provided.

It is an object of the invention to provide such a control for a truck or the like, or for a motor, that, by the operation of a single actuator into any of a plurality of positions, can obtain a plurality of speeds of the motive means, either forward or reverse, which is relatively simple and more compact than those heretofore obtained.

A further object is to provide a control of this type that will prevent excessively rapid shifts of the speed control and excessive currents through the motor and interposed switch devices, that might injure the motive means, shorten its life, and cause excessive Wear upon the circuit breakers. Especially is it an object to attain the foregoing where the control is operated to reverse the direction of the motive means. It is a particular object to accomplish the foregoing by the interposition of a timing means into the control that will prevent unduly rapid shifts, and will reduce high current through the motor and switches as a result of speed changes. Another object is to attain the foregoing, in regard to a shift of direction of the motive means, by a hold-out control that is operated When the control is reversed by employing the electric motor motive means as a generator as a result of overtravel of the vehicle. until the motor has at least substantially reached a condition where it reverses its own direction of travel. Another object is to provide rapid shifting of direction between low speeds, to en able the truck to be worked into tight places.

Further objects include the provision of means to adjust the speed of the timing mechanism that controls the speed of the shifts; the provision of a dependable timing arrangement not subject to variation from conditions such as temperature changes; the provision of a particularlv compact arrangement of cam switches to control the various speed responses; the provision of a foot actuatable control in addition to a normally manually actuatable control element; the arrangement of the foot control to afford rapid stopping of the motor, and for rapid acceleration only when another control has been cperated to select direction; and the intercon necticn of the actuating means with the cams the timing mechanism to permit the actuating member to move in advance of the cams, set the timing mechanism in operation, so that the latter ultimately permits the cams to follow up to the positions chosen by the actuating member.

Other objects will appear from the details of the description to follow and from the drawings. In the latter:

Fig. 1 (Sheet 1) is a front elevation of the control;

Fig. 2 is a side elevation thereof, taken from the right side of Fig. 1;

Fig. 3 is a rear elevation of the control;

Fig. 4 (Sheet 2) is a left side elevation of the control partly in section;

Fig. 5 (Sheet 3) is a iront view of the control with the front cover removed and with parts shown in section;

Fig. 6 (Sheet l) is a front elevation with the front cover removed;

Fig. 7 is a section on the line 1--1 of Fig. 6, showing the operating levers;

Fig. 8 is a section on the line 8-8 of Fig. 6;

Fig. 9 is a vertical section on the line`9-9 of Fig. 6, showing particularly the operation of the foot operated detent release;

Fig. 10 (Sheet 4) is a view of the upper part of the control appearing in Fig. 6, but with a bracket shown in section;

Fig. 11 is a front-to-rear section on the line Il-Il of Fig. 10;

Fig. 12 is a vertical front-to-rear section taken on the line l2-I2 of Fig. 6;

Fig. 13 is a vertical front-to-rear section taken on the line |3-I3 of Fig. 6;

Fig. 14 (Sheet 5) is a horizontal section taken on the line lli- I4 of Fig. 1;

Fig. l5 (Sheet 3) is a vertical section, taken on the line I5-l5 toward the right-hand end of Y, the upper shaft in Fig. 5, showing handle return mechanism;

Fig. 16 (Sheet 5) is a horizontal section. on the line lE-IS extending brokenly across the lower end of Fig. 5, giving a plan view of the timing mechanism and solenoid;

Fig. 17 is a vertical section taken on the line i'l-ll at the right of Fig. 16;

Fig. 18 (Sheet 6) is a section through the timing mechanism on the line I8-l8 of Fig. 16;

Fig. 19 is a section on the line IE5-19 of Fig. 16;

Fig. 20 (Sheet 1) is a View of the foot operated detent release mechanism, taken from the right side of the control, turned somewhat from normal position;

Fig. 21 is a section on the line 2-l-2l of Fig. 20;

Fig. 22 is a view of the detent rocker arm, taken from the left;

Fig. 23 is a view of the detent arm, taken from the right of Fig. 22;

Fig. 24 is a side elevation of the foot latch arm;

Fig. 25 (Sheet 2) is a left side elevation of linkage for the speed cam operation; A

Fig. 26 is a section on the line 26--26 of Fig. '25;

Fig. 27 is a left side elevation of a cam roller arm assembly employed in the linkage for operating the speed cams;

Fig. 28 is a bottom plan view of the arm of Fig. 27;

Fig. 29 (Sheet 3) is a side elevation yof the detent torsion spring;

Fig. 30 is a front elevation ofthe foot latching arm torsion spring;

Fig. 31 is a side elevation thereof;

Fig. 32 (Sheet 4) is a side elevation partly in section of the index plate and cams mounted on the upper shaft;

Fig. 33 is an end view of the cam structure and .the indexing plate, taken from the vleft of Fig. :32 and from the left side of the casing;

Fig. 34 is a view of the cam assembly taken vfrom the right side of the casing and the right side of Fig. 32;

Fig. 35 is a section on ,the line 35-35 of Fig. 32;

Fig. 36 is an end view of the indexing .Cam plate;

Fig. 37 is a fragmentary View of the front casing section, showing how it is flanged to intert with the rear casing section;

Fig. 33 (Sheet '7) is a front elevation of the cam switch subassembly and lock;

Fig. 39 is a side elevation of the subassembly of Fig. 38, taken from the left thereof;

Fig. 40 (Sheet 2) is a plan View of the right side of the timing mechanism assembly, showing the balance `lever' and adjustment therefor;

Fig. 41 is a left side elevation of the mechanism appearing in Fig. 40;

Fig. 42 is a right side elevation of the assembly appearing in Fig. 40;

Fig. 43 (Sheet 6) is a view of :the left side of the timing mechanism;

Fig. 44 is a plan view partly in section of the left part of the timing vmechanism and the solenoid;

Fig. 45 is a view of the ratchet wheel and gear .assembly used in the timing mechanism;

Fig. 46 is a side elevation of the ratchet wheel;

Fig. 47 is an edge view of the .balance wheel;

Fig. 48 (Sheet 5) is a plan view of Ythe escapement lever` and shaft;

Fig. 49 is a perspective view of the pin device for the escapement lever;

Fig. 50 is a front elevation of the escapement lever, taken on the line 50--50 of Fig. 48;

Fig. 51 is an edge view of the timing mechanism winding sector and arm;

Fig. 52 is a right side elevational View thereof;

Fig. 53 is a side elevation of the solenoid switch lever;

Fig. 54 is an elevation of the wire pin means for the balance wheel lever;

Fig. 55 is a face view of the ratchet gear;

Fig. 56 is an edge view of the ratchet gear of Fig. 55;

Fig. 57 is an end view of the balance wheel lever assembly;

Fig. 58 (Sheet 8) is a schematic wiring diagram of the truck and the control; and

Figs. 59 through 63 are schematic Views of various combinations of operation of the truck obtainable with the present control.

The control itself is here illustrated as being enclosed within a strong casing G0 that preferably has a rear section 6| and a removable front cover 62. There are two main shafts in the rear section 6| of the casing. The upper shaft, indicated at 64, vextends from side to side ofthe casing through the side Walls thereof and h has suitable bearings [i5 and 66 in those walls.

'The lower shaft 51 is mounted in one side wall of the back casing element 6I. The casing is provided With a bushing @il that is secured to the side wall and affords an elongated sleeve that can give a cantilever-like support to the shaft Bl.

.An elongated actuator 'it is connected with both of the shafts Gil and 51. The actuator 13 has .a handle knob 7| at its outer end, and at its lower end is given a channel shape, and is welded or otherwise secured at its bottom tc a bushing 'l2 that rocks freely on the outside of a shouldered portion .of the bushing 63 that supports the shaft 61.

Adjacent the sliait the handle iii 'i3 that extends through the web of he channellike Vportion of the handle at tb location. A pivot pin 'i4 passes through th" 1n has a flange 'i5 on it that engages a roller l so that the pin 'M may slide i eely in channel within the limits of the slot A movable pin and washer i lil in place.

.h as a slot ble relike manner to a cranl; lever at its lower end is attached in manner to a collar what reduced outer end of the shaft held in non-rotatable engag ment the a Woodruff lfzey til. The rivet atta described Vbe enforced by oth as solder. The assembly of the le er cured to the shaft by ineens such as an end thrust plate E that is held a screw to c end of the shaft dii, and which a the lever From the foregoing, it may be seen the t, wi the handle 'il is moved, the actuator a r rock about the center o the lows.. s t i. in-: will displace the pin and will cause the cra l.

.lever 'I9 to roel; the shaft dit. This movement of cani.

cam plate notches in its edge, lthe 1r.

erating conditions. For e ample, notch 9| is the neutral not mediately to one side of i establishes forward direction; the other notch 93 flanking the notch 3l -stablishes reverse direction. The notches 551, iid establish different forward speeds, and the er notches Q8, 99, im) and itil establish diilerent reverse speeds.

There is an index roller that act" with the various index notches as a detcnt means. This index roller i3d is supported at the eind of en index arm itil (detail, 22, 23). lhaiu arm, in turn, is pivoted in a bracket to the top of the casing member 8 i. 05 has a pin through depending ears, which pin passe through a suitaole opening' in the upper end of the index arm itil. A torsion spring lOl surrounds the rocker pin its yends suitably connected apply t 'line hraclzot urge the arm |34 in a direction to yieldably engage the roller |23 in one or the other of the index plate notches.

The index arm has a ledge |08 that is at right angles from one of the two side edges of the arm adjacent its lower end. This ledge |38 has a hole |33 through it for a purpose to appear.

There is a foot control latch connected between the lower shaft '31 and the arm |03. Figs. 20 and 21 show the operating parts of this arrangement in detail; and the foot control members are shown in other views, as will appear.

The shaft 31 projects outwardly of the casing 6| beyond the lower end of the actuating arm 10 and is reduced somewhat in diameter. This outer portion of the shaft 61 receives the hub H2 of a foot control lever H3. The lever ||3 extends out in a fashion so that it can be attached to a pedal at some suitable point on the truck. Fig. a shows that there is a notch and lug arrangement i ifi between the hub l |2 and the lever H3 to assure that these parts rotate together. They also may be otherwise attached. They are held to the shaft 6? by an end plate I5 and screw H6, or other like attachments. A Woodruff key H1 causes the foot control lever ||3 to rotate with the shaft Si.

Inside the casing, the shaft 61 projects beyond the bushing S8. This projecting end receives a bushing portion H3 that is securely attached to a hub portion ile of an arm |20. The hub H9 has opposed arcuate notches i2! that receive the ends of a pin |22 (compare Fig. 13) that is secured through the shaft 31. Consequently, as the shaft rotates, the pin will have some lost motion but then will engage either the clockwise or counterclockwise ends of the notches |2| to cause rocking of the arm |20.

The arm |23 pivotally receives the lower end of a looped latch member |23. The loop in this latch member enables it to pass around the upper shaft 54 as is indicated in Fig. 9. Beyond the loop, the member |22 has a projecting pin-like portion |24 that passes through the hole |39 in the ledge |33 of the indexing arm |34. Reference to Fig. 9 will show that, if the arm |20 be rocked counterclockwise in that view, the pin |24. will slide within the opening |33 of the arm |34 until the rounded part of the member |23 engages the ledge |33 and causes the arm |34 to be rocked. in a direction to disengage the roller |33 from the notches of the index plate 90.

It will be seen by reference to Figs. 20 and 2l, and also Fig. 5 and other views, that the member |23 adjacent its pivotal connection to the arm |22 has flanges |25 that form its lower end into a channel-shaped element. There are holes |25 through these flanges |25. These flanges are adapted to provide pivotal support for a foot lever latch element |23 shown in detail in Fig. 24. A pin |29 passes through the holes |25 and a suitable hole |3 in the foot lever latch |28 to provide this pivotal support.

The latch |28 is made from a generally U-shaped cross section by forming sheet metal. t thus has side flanges joined by an upper connecting member |3| and a lower connecting member |32. The upper connecting member |3| preferably affords a sloping cross section for a purpose to appear.

The indexing plate 93 adjacent its lower end has a stamped-out portion |33 that is positioned to cross the path of the sloping connecting portion |3| of the latch member |28. These two parts are shown in engaged position in Fig. 5.

4|33 will be withdrawn from the latch |28.

Of course. if the index plate 90 is rotated about the shaft axis 64, the displacement cam portion This latch |28 is engaged by a torsion spring |34 that urges its upper end away from the nearby side of the casing, which is to the right in Fig. 5.

Slightly above and to one side of the lower shaft 61, the casing supports a stud shaft |33. On this shaft, a cam rocker arm |33 is mounted. This cam rocker arm appears in detail in Figs. 27 and 28, and appears in other views in assembly. As shown in Fig. 28, it has an elongated hub |40 at its lower end, this hub being mounted on the pin |38 as appears in Fig. 5. A coil torsion spring |4| surrounds this hub and is suitably attached at its ends to apply a force that rotates or tends to rock the upper end of the arm |33 toward the axis of the shaft 64.

The cam lever |39 has a cam roller |42 between its ends. This cam roller is positioned to engage the lower edge |43 of the indexing cam 30. The shape of this edge |43 is shown in Fig. 36. The relative position of the roller |42 when the cam 90 is in neutral position is indicated by dotted lines. There is a portion of the edge |43 of uniform radius adjacent the neutral point, followed by additional convex portions of increasing radial distance from the axis of the plate 90.

The upper end of the arm |39 is pivotally connected to a link |44 that is pivoted, in turn, to a crank arm |45. These parts are shown in detail in Fig. 25. As shown particularly in Fig. 26, the arm |45 is mounted upon a hub |41. This hub is shown in Fig. 5 and is rotatably mounted upon a bushing member |48 that, in turn, is mounted upon the shaft |34.

The arm |45 has a backwardly projecting pin |50, over which the inner end of a flat coil spring |5| is looped. As will appear, this coil spring transmits torsion to the cams that operate switches of this control. The other end of this coil spring is attached to a pin |52 that is mounted on and extends through the radial wall of a cam drum |53. The end view of the cam drum |53 appears in Fig. 35 in full lines. This cam drum |53 is attached in back-to-back relationship with another cam drum |54 against a shoulder on the bushing |43 by a permanent connection. The cam |53 has an axial projection |55 on its periphery that engages the upper end of the crank arm |45 under influence of the coil spring |5|.

From the foregoing, it will be understood that, when the cam lever |39 is operated to draw upon the link |44 and rock the crank |45, this crank, through the medium of the pin |52 will tighten the spring |5| and may rotate both of the cam drums |53 and |54, the force being transmitted tlgough the pin |52 mounted upon the cam drum An elongated link |56, having a slot |51 at its upper end, is likewise mounted upon the pin |52 and depends therefrom to a timing mechanism for a purpose that will appear later.

Beyond the hub |48 that supports the two cam drums |53 and |54, there is an additional hub that is pinned at |56 to the shaft 54. This huh supports an additional forward and reverse cam drum |61. The periphery of the cam drum |61 has a finger |58 projecting therefrom parallel to the axis. The finger |53 is adapted to actuate a handle return spring mechanism shown in Fig. l5 in end elevation, and shown in section in Fig. 5.

The handle return spring mechanism includes a hub |10 rotatably mounted upon the hub |35.

`A `ring |1| is permanently attached to the hub |10. This ring has an upstanding finger |12 pr.0- jecting generally radially outwardly and adjacent this it has a ledge-like flat portion |13. t interfits against a cup |14 that is rotatable on the outer surface of the hub |10 and is held thereon by means such as those indicated in Fig. 5. The cup has a finger |11 that is similar to the finger i12 of the plate |1|, as is indicated in Fig. l5. A torsion coil spring |10 has one end attached around a locking pin |13 that is attached firmly to the hub |10. As is indicated, there are a plurality of notches |16 arranged around the periphery of the cup |14 to receive the hooked outer end of the torsion spring |16 so that it may be liter or loose-r as desired. The effect `of .t ls to draw the fingers E12 and |11 together until they are held in the spaced relation indicated in l5, by the portion |13 upon the plate |11.

A bracket 55 is attached to the housing by any suitable means, and it has a fixed ledge |8| that projects between the two fingers |12 and |11.

From the foregoing, it will be seen that rocking of the shaft 64 rocks the forward and reverse cam drum |51. The finger |66 on this drum lits between the two fingers |12 and |11 on the spring return. If the cam |61 is rotated in a counterclockwise direction looking from the left of Fig. 5 and from the front of Fig. 15, the 1.

finger |68 will displace the nger |12 but the other finger |11 will he held by the bracket ledge |8|. Such displacement of the linger |12 will separate the lingers |12 and |11, tightening the torsion springl |16, so that a return force is applied. t will be evident that operation of the shaft in the opposite direction produces a similar displacement of the finger |11 with attendant tightening of the spring. This mechanism thereby applies a return force to the shaft 54 when-4 ever it is displaced from its neutral position. This force is not enough to overcome that-of the detent means on the indexing plate 90.

The cams actuate a plurality of switches.

These switches form a part of a subassembly that .,f

is removably applied to the casing so that the switches may be actuated by the several cams. This assembly includes a fairly large plate |90 that is Ll-shaped in cross section, so as to provide opposite side portions |9| and |92. These side portions i'lt within the side walls of the back casing member 6| so that the front panel extends across the opening cf the back section 6|. The two side parts are then held to the side parts of the casing 6| by screws as illustrated in Fig.

1.4. .A lock |93 is mounted on the bracket |90 and is interconnected with the electrical mechanism. A suitable opening extends through the front casing 62 -for reception of the lock hole to render the same accessible from outside the mechanism.

Back of the front plate of the bracket |90, there is a supporting plate |94 that is flanged on all four of its sides. Its side flanges lie just inside the side walls |9| and |92 of the bracket |90 and are riveted thereto as at |95. It has an upper flange |96 and a lower flange |91 that support switch blade assemblies, all of which are alike in construction. There are three upper switch blade assemblies 250, 20| and 202, and three lower switch blade assemblies 253, 204 and 205. As shown particularly in Fig. 39, each switch blade assembly provides, two spring blades 206 and 201 that have contacts cn them. These blades are normally open to part their contacts by their normal springing character. Each blade 201,

`8 which is the inner blade of each switch, has an insulativc cam follower 208 on it. The two blades are of course maintained insulated from one another and are provided with the proper connections for the circuits to be described hercafter.

When the cam switch subassembly is put together in the manner aforesaid, it can be inserted into the back casing section 6| and thereto attached. When so positioned, it will dispose the cam followers adjacent the several cam drums |53, |54 and |61. The switches 200 and 203 are diametrically oppositely arranged with respect to the cam drum |53. This cam drum is shown in Fig. 35 as having a fairly extensive upper cam rise 2|0 and a less extensive lower cam rise 2| I. Fig. 35 shows the cam drum |53 in its neutral position. As will appear from the description of the operation, the two cams |53 and |54 always move in the same direction from neutral position regardless of the direction of movement of the handle 10 and the shaft 64. Consequently movement of the cam drum |53 clockwise in Fig. 35 will shortly close both of the two switches 200 and 203, but will release the switch 203 before it releases the switch 200, owing to the greater arcuate length of the cam rise 2|0 than the cam rise 2| The cam drum |54 operates the switches 20| and 204. As shown in Fig. 35, this cam drum has a relatively short upper rise, indicated largely in dotted lines at 2|3, and a longer lower rise 2|4. Hence the clockwise rotation of the cam drum |54 will close the switch 20| for a short period, and upon further rotation will close the switch 204.

The forward and reverse cam drum |61 is rocked in the same direction as the shaft 64, which shaft rotates in accordance with the direction of displacement of the handle 16 from neutral position. The position of the cam drum |61 in neutral is shown in Fig. 34, at which time both of the switches 202 and 205 are opened. The cam drum |61 has a single rise 2|5 that is displaced under one or the other of the two switches 202 and 205, depending on the direction of rocking of the cam drum |61. Thus one of these switches will be closed and the other left open whenever the shaft is rocked. This rise is effective before any of the rises on the cams |53 and |54 acts upon their switches.

As previously described, the rocking of the handle 10 in either direction will cause angular displacement of the crank arm |45, and this will similarly cause displacement of the pin |55 in a. direction to wind up the torsion spring |55 that is connected to the drum |53 to rotate both it and the drum |54. During the early part of the movement of the pin |50 aforesaid, two drums |53 and |54 will follow the movement of the pin. However, the movement of the two cam drums |53 and |54 into their higher speed positions is regulated by a timing mechanism that controls the speed at which a change from one high speed position of the cam to another may be obtained, and especially that prevents the complete shifting of the direction of movement of the truck. from forward to reverse, or vico versa, without giving the truck motor time to slow down.

The foregoing timing mechanism. is couirolle through the link |56 that is attached a pin and slot arrangement to the |53 and |54. This link |56 extends dowi. as shown in the .center of Fig. 5 into escapement device.

Fig. 16 shows that the escapement mechanism is contained between two side plates 226 and 221 that are held in spaced relation by suitable spacer rods 228 or the like and with the assembly removably mounted onto the back and bottom of the back casing section 6| by suitable screws 229.

Mounted at one of its ends in the plate 226 is a xed shaft 236. This shaft extends toward the other plate 221 a limited distance, and at its other end is mounted in one end of a striplike plate 23|. The plate 23| receives a screw 232 that attaches it into the shaft 239 that maintains its position away from the plate 226. At its lower end, it receives another screw 283 engaging a similar shaft device that extends back to the plate 226.

The link |56 that is attached by the slot connection to the cam drums |53 and |54 extends downwardly to the timing mechanism and is pivoted at 234 to a crank arm 235. This crank arm 235 is integrally attached about a hub 236 that also has attached to it a gear sector 231 (detail, Figs. 51, 52). The hub 266 extends away from the plate 226 and is supported upon the shaft 236 between the plates 226 and 23| for rocking thereon.

The gear sector 231 meshes with a gear 249 that is rotatably mounted upon the xed spacer shaft 239 attached between the lower end of the which gear has a ratchet dog 244 pivoted thereon at 245 and spring-urged by a spring 246 to bring its actuating end toward the axis (details, Figs. 55, 56). As shown in Fig. 43, this arrangement will permit the link |56 to rock the sector 231 when the link is drawn upwardly, provided only that the gear 243 may be rotated. If the gear 243 cannot rotate, then the ratchet dog 244 on that gear will engage the ratchet wheel 24| and prevent rotation of the gear 249. As will appear hereafter, therefore, this puts a limit on the amount of free rotation that the drums |53 and |54 can have upon rotation of the handle. Operation of the handle beyond such limits of free rotation will merely further wind up the coil spring and apply a strong upward pull on the link |56.

The gear 243 meshes with a small gear 249 that is on an escapement shaft 250. The escapement shaft 250 supports an escapement Wheel that rotates with the shaft. The shaft 256 is mounted between the two plates 226 and 221.

Cooperating with the escapement wheel 25|, there is an escapement lever generally indicated at 252, it being mounted to rock upon a pin 253 that is supported between the plates 226 and 221. This escapement lever, as an assembly, is shown in Figs. 48, 49 and 50. It comprises a main plate member in the form of a lever, one arm of which has an elongated slot 255 in it. A wire member 256 is bent to the shape illustrated so that its central portion extends like a V over the hub of the lever and so that it presents two projecting pins 251 and 258 that pass through holes in the other arm of the escapement lever 252, which two pins constitute the escapement pins that cooperate with the escapement wheel 25 as is evident from Fig. 16. In addition, there is a stop element attached to the escapement lever. It includes a spring-like element 269 riveted to one portion of the escapement lever 252 and projecting therebeyond, so that its free end may yield away from the lever. However, it may not move in the other direction beyond the plane of the lever. This will be evident from Fig. 50 wherein the spring plate 268 is shown as superposed over one face of the lever. A rigid stop plate 262 is riveted at 263 to the free end of the spring plate 260 for a purpose to be described.

The slot 255 in the escapement lever is employed in connecting the escapement wheel to an inertia balance wheel. To this end, a balance wheel lever of somewhat zigzag shape is shown at 268 (Figs. 40, 41, 42 and 57). The balance wheel lever 268 is pivoted at 269 in balanced manner onto a bracket 210 that constitutes a projection of a slide bar 21|. The slide bar is supported on the plate 221 for sliding movement fore and aft. To accomplish this, there are headed rivets 212 that pass through slots 213 in the plate 221. The slide bar has a bent-over end 214 by which it may be manually engaged to be moved toward the front or rear of the casing. By this means, the balance wheel lever may be bodily displaced at its pivot 259, forwardly or rearwardly 0f the casing.

The forward end of the balance wheel lever 268 is initially provided with a slot 218 and a hole 219. A wire spring member 286, as illustrated in Fig. 54, is provided with a reentrant bent portion 23| and a projecting pin portion 282. This member is inserted into the end of the balance wheel lever with the reentrant 28| engaged within the slot 218 and the pin 262 projecting through the hole 219. Thereafter, the portions of the balance wheel lever adjacent the slot are crimped together to hold this element in place. The pin 282, when the balance wheel lever is in its operative position, projects outward through the slot 255 in the escapement lever, and by it comprises connection. The rocking of the escapement lever is caused to rock the balance wheel lever.

The back end of the balance wheel lever receive-s a similar spring wire member 285 that has a projecting pin 286. This pin 286 engages in a slot 281 of a ily wheel 288. The fly wheel is mounted on a shaft 289 that extends from the plate 23| to the side plate 221.

When the gear 243 rotates, it rotates the gear 249 and the escapement wheel 25|. The teeth on the escapement wheel are shaped and positioned in familiar manner to alternately engage the two pins 251 and 258 that project from the escapement lever 252 so that that lever is rocked about its pivot 253. Only by such rocking movement can the escapement wheel 25| rotate. As the escapement lever 252 oscillates, it rocks the pin 282 on the balance Wheel lever and causes that lever to rock about its movable pivot 269. As the balance Wheel lever 268 is also connected by a rocking pin 286 to the balance Wheel 288, it causes that balance wheel 288, which is relatively massive, to rock back and forth with each oscillation cycle of the escapement lever 252.

A shifting back or forward of the slide bar 21| that supports the pivot 269 of the balance wheel lever 268 changes the leverage ratios of the foregoing escapement mechanism. If the slide bar and the two pins 282 and 286 are moved backwardly from their positions in Fig. 18, the leverage of the escapement wheel 25| upon the escapement lever 252 will increase, but the amount of angular movement of the balance,

wheel 268 will decrease. At the same time, the

"il leverage of the balance wheel lever 268 on the balance wheel 288 will decrease. When the slide bar 21| is toward the back of the casing, the escapement will be most rapid. As the slide bar is moved forwardly, the escapement becomes slower.

As shown in Fig. 18, the escapement lever 252 is in a neutral or mid position. In that view, immediately below the stop plate 262 of the escapement lever 252, there is a circular blocker member 292. Reference to Fig. will show that this blocker member may be so located as to be interposed beneath the stop plate 262. Comparing Fig. 18, the blocker 292 will therefore, under such circumstances, prevent the full oscillation of the escapement lever 252, and can block the rotation of the escapement wheel 25|.

The previously mentioned blocker 292 is attached to the core of a solenoid, generally indicated at 294. This solenoid includes coil means 295 and 296 duly provided around a core and enclosed within a cup 291 that is attached to the outside of the plate 225. The plate has a hole for the end of the core to pass through it.

On the inside of the plate 226, there is mounted an insulative plate 33t. On the inside of the plate 300, there is mounted a pivot bracket 30| (particularly Fig. 53). This bracket has two downwardly turned side legs 302, by which it is attached to the plate 300. The material from between these legs is stamped backwardly, as shown at 303, to support a first spring hinge member 304. This spring hinge member has an insulative plate 305 riveted to it, at the lower end of which is riveted another spring hinge plate 306 that is forked, as shown in Fig, 19, to support the contacts 301 and 308. The plate 300 supports two xed contact brackets 309 and 3|0 that are adapted to be engaged, respectively, by

the contacts 301 and 308 on the switch blade 300.

The springing of the plates 304 and 305 is such as to engage the contacts in closed relationship normally. When the plate is moved in the opposite direction about its pivot hinge 304, its contacts 301 and 308 are engaged with two other xed contacts 3|| and 3|2, the latter crossing over and turning down under the switch blade.

As shown in Fig. 16 particularly, the upwardly projecting edge of the bracket 30| has a recess 3|5 cut therein. An actuating lever 3|3 has a rounded head that is notched at 3| 4 so that it may be pivotally engaged within the recess 3|2. This lever is somewhat bent, as shown in Fig. 5, and has its lower end bifurcated and rounded off at 3H;` so as to be engaged under the blocker head 292 on the core of the solenoid. A coil spring 3|1 at the upper end of this lever 3|3 acts to urge the lower end 3|6 against the head 292. This coil spring is attached to an adjustment screw 3| 3 that is threaded into the plate 226 and locked by a lock nut 32B, as shown in Fig. 5. By this means, the tension of the spring 3I1 may be varied. By this means, an adjustment can be made to Vary the speed in which motor will reverse direction. As will appear, the return of the handle to neutral position causes the shaft 64 to return, and the return spring returns the cam |61 at a speed liked by the torsional force of the spring |10.

Adjacent its lower end, the lever 3|3 may engage the insulative plate 305 of the switch blade so as to displace the contacts 301 and 308 from their respective fixed contacts and thus shift the solenoid switch. In addition, when the coil means are properly energized, the blocker 292 will withdraw from the path of the escapement lever 252 and permit the same to oscillate. if it returns during a period in the oscillation when the stop plate 262 is in its path, it will dei'lect the stop plate by deforming the bronze )late 269.

The lower end of the plate 300 also supports a contact 325 that acts as a terminal.

As shown in Fig. de, the solenoid plunger an enlarged magnetic portion il attached thereto and closely spaced with respect to the two coils 29d and 295 so as to be attracted thereiiy.

The two coils 295 and 295 are wound aron .l brass sleeves. The two separated by a anag netic disc flanked by suitable plastic insulator discs and surrounding and magnetically attached to a magnetically conducting sleeve L Siniilar steel plates 334 and 335 provided at the ends of the coils. There are Bakelite or si: nilar insulators at the outer ends ci the coils. i 5531 of magnetic material has a Lilli-i of like material at its middle, this sleeve receiving the core and extending axially inwardly. A similar hollow cup of magnetic material is attached to the inside of the cup The core causes the collar 330 to reciprocate `between the members .33B and 309.

The wiring of the arrangement is shown schematically in Fig. 58, with certain combina tions illustrated in abbreviation in Figs. 5D through 63.

In Fig. `58, the cam actuated switches are shown as operated by a different type of cam because of clarity in diagrammatic illustration. This type of cam is not as desirable -as the one illustrate-il in detail.

Referring particularly to Fig. 5S, there is shown a drive motor 350 having a field winding and a combination series resistor and 353. A a battery is shown at 355. As a .matter oi' detail, a horn is shown at 355 with a horn button these being connected directly across the battery. There is also a seat switch that constitutes a master control switch to prevent opera-- tion of the truck when the seat is not occupied.

In addition, there are four relays provit :l i'or the truck. These are shown at and The relay 360 has a coil 365 and a dcublepole, double-throw armature 365 that is adapted to close either a set of contacts 351 when the coil is deenergized or a set of contacts when the coil is energized. In addition, the core of the coil closes a holding switch 369 when the coil 355 is energized.

The relay 236| includes a coil 3153 adapted to actuate an armature 31| that normally closes with a pair of contacts 311, but, when energized, is energized, closes pair of contacts This core also closes a. holding switch Ell-'Ll when the coil is energized. The relay 352 includes 315 with an armature 310 that normally with a pair of contacts 3i?, but, when one.' closes a pair of contacts The rela clude a coil 38) that has an arniatine mally closing with a pair of contacts which closes with pair of contacts 36d it is energized.

The positive side o1 the battery aA lead Titi-F that is connected to one side of each oi' the relay coils 365, 315, 315 and 33t. "he side of the battery is connected by a lead del tl leads to one contact each of the Contact set. yand llll of the relays 360 and 35|, respectiv Another' line A02 leads from the negative side of the battery over through a fuse F, and the .lock` |93, to one side of each of the four cam-operated switches 200, 20|, 203 and 204.

The drive motor 35% is connectedfby one line 523 to the positive lead 455 from the battery. The other side of the motor armature is connected directly into one end of the series resistor 352 and it is also connected by la line 455i into one contact of the relay 955. The upper end ol' the resistor 352 is connected by a line 405 to one ci the contacts 315 of the relay 362. The upper or outer end oi" the resistor 353 is connected by a line 455 that leads to one of the contacts 35i? of the lower relay 350, to one of the contacts 312 of the relay 36|, to one of the contacts 21 of the relay 552, and to one of the contacts of the relay The series field Winding 35| of the motor is connected to a line 458 that leads from one of the contacts 312 and one of the contacts 313 of the relay S l. The other end of the iield Winding is connected by a line 459 to one of the contacts and one of the contacts 353 of the relay 595.

The two adjacent contacts Il'll and 382 of the relays and are connected by a line 4||l that also connects together adjacent contacts 319 and of the same two relays.

It will be understood that the partsv in the right-hand section of Fig. 58 represent connections within the control box 6l. The leads are brought out through the plug terminal 4|5 at the bottom o1" the back casing section 6l.

rihe line 552 that runs from the negative side of the battery through the seat switch 358 extends through the iuse and through the lock |93, and thence to one side of each ci the switches 25|, 253 and 204. The other side of the switch 255 leads by a line 42|) to the main winding of the solenoid 294. The other side of this coil leads by a line 42| into the line 4110 on the positive side of the battery. In addition, the line connects with a branch wire 422 that connects into one side oi each of the switches 359 and i514. If one or the other of the coils 355 or 515 is energized, one of the two switches mentioned will be closed and the foregoing wire 422 will be connected with a wire 423. The Wire 423 connects into the movable contacts of both of the forward and reverse switches 252 and 265. A branch 42d from the line 423 leads to one contact 3|2 of the solenoid switch.

The other contact of the forward directional switch 255 is connected by a wire 425 that leads into one end of the coil 355 of the rst truck relay 359, the other end of which is connected with the positive side of the battery.

The fixed contact of the reversing switch 202 is connected by a wire 426 that leads into one side of the coil 315 of the second truck relay 36|, and thence to the positive side of the battery. It will later appear that the relay 36B is a forward directional relay, and the relay 36| is a reverse directional relay.

The cameactuated switch 25| has its xed contact connected by a line 435 to the contact 3|| of the switch actuated by energization of the solenoid 294.

The fixed contact of the cam-operated switch 253 is connected by a wire 432 that connects into the coil 515 of the relay 352. The camoperated switch 254 has its fixed contacts connected by a wire 433 that leads to the coil 339 of the relay 353. A wire 435 connects one side of the motor 35|] to the contact 3H! of the solenoid 294, closed with the contact 309 when the core is out.

As illustrated in the Wiring diagram of Fig.

14 58, the actuating arm 15 rotates a shaft that also rotates the cam |51 to actuate the forward and reverse switches. It is also illustrated schematically as having a double cam arrangement 44u projecting below the shaft that, when rotated in eitner direction from the neutral position shown, depresses a fori; 44| that drives the two cam holding rods downwardly. An analysis will indicate that the operation of this is the equivalent of the operation of the cams illustrated in the detailed structural description, insofar as the wiring circuits are concerned.

Operation When the actuating arm l5 is in the neutral position, the indexing cam 5c will have its cam roller |53 disposed in uetaining liasnion in trie notcii 5|. 'ine lower edge les oi' the indexing cam plate Wiil have its middle arcuate portion against the cam roller las on the arm iss, so tiiat the arm |55 is pivoted or rocieoi on its pin |35 to dispose its upper end as close to the center or' the shalt 5e as it ever can get. 'ihis will cause the crank |45 that is attached to the bushing |41 to rotate to its maximum counterclockwise position, viewed iroin the actuating handle side oi' the control box. The torsion spring |51 will draw the cain drum |55` clocl wise a maximum distance until the finger |55 on the edge of the cani drum E55 engages against the upper end of the arm |55. This will stabilize both oi' the cam drums |53 and |54 in their neutral position, so that all of the switches 255, 29 I, 203 and 254 are opened.

At this time, as illustrated in Fig. 5, the outwardly struck portion |33 on the lower end of the indexing plate is engaged under the conn necting portion |3| on the root operated latch lever, holding the shoulder formed by the inner end of this connecting portion i3! away from the roller |412 that is on the lever |35. As a result of this positioning of the latch lever |2li, rocking of the foot crank H3 and attendant rotation of the lower shaft 5l', and reciting of ,the cross pin |22 in 'the notches |2l, cannot displace thelink |35. Rather, the connecting poi tion |3| on the latch lever by the aforesaid action of the foot crank H3 will be drawn down over the face of the roller |42 without performing any work thereon.

The directional cam |51 will be in its neutral position, with the nger |58 disposed between the two arms |12 and |11 on the handle return device, and with the iinger |58 also disposed directly above the bracket projection i8 In the neutral position of the cams |55 and |54, the pin |52 will be disposed at the bottom of the slot |51 in the link |55 that connects into the timing mechanism. As a result, these parts will be in the position shown in Fig. 19 where the gear sector 23'! is in position to operate a full stroke on the gear 24U.

At the start, the solenoid 254 will have its coils deenergized and its core released, and the coil spring 3|1 rocking the lever 3|3 will cause the head 292 on the core of the solenoid to be out in the position indicated in Fig. 18 wherein it engages the stop plate 262 on the escapement lever 252 to prevent the timing mechanism or escapement device from functioning. Also, the solenoid switch contacts 359 and Slo will be closed, and the contacts 3|| and 3|2 will be open.

Assuming that the connections are made as they appear in Fig. 58 and that the seat switch 358 is closed by the fact that an operator is in the truck and occupying the seat, the line 4M! from the positive side of the battery will be com nected to one end of each of the truck relay coils. The negative side of the battery will be connected through the fuse and the lock |53, When the lock is operated by its key, it will close a switch so that the line 452 may continue to the movable contacts of all of the camoperated switches D, 20|, 293 and 2M.

To initiate operation of the control, the iirst step is to rock the actuating arm 1U one Step forward or backward. Assuming that it is desired to move the truck forward, the handle will be moved one step forward. Ohe step forward is attained when the pin T4 passing through the handle displaces the crank lever l5 keyed at 8| t the shaft a sufficient arcuate distance toca's the indexing plate 9G to rock so that the notch 9| thereon is displaced from the roller |33 on the detent mechanism and the notch 92 is moved under the detent roller |53. At the same time, the pin |65 on the shaft E4 will displace the hub IE5 and the directional cern |61 an equal angular distance. This will cause the iinger |68 on the cam to move the projection Ill on the cup |14 and partially wind the spring llli so that lthe same applies a return force to the shaft 64 that can return the shait whenever the detent roller is withdrawn from the indexing pla-te llc. Also, such rotation of the cam |51 causes its rise 2 I 6 to close the bottom switch 205 in Fig. 5 and in Fig 58. As will appear from the wiring diagram in the' discussion to follow, this pre-establishes the direc# tion of the drive motor 35!! for subsequent movements at various speeds.

Such slight rocking of the indexing plate 9|! as is caused by moving it the distance of one notch in either direction from the neutral notch SI does not displace the cam roller |42 on the link |39 of the speed responsive cam drive mechanism because the crm roller |42 in such movement remains on the arcuate portion of the edge |43, and hence is not displaced radially by the indexing cam S0. However, such rotation is suiicient to withdraw the rise |33 on the lower part of the indexing cani Sill from the connecting portion |3| on the latch lever |23, so that the spring |34 can move the connecting` portion over the cam roller |42. This predisposes the parts for` certain operations by the foot pedal that will bel described separately hereafter. v

If the operator then advances the handle another notch. so that the indexing cam-5i) is moved to dispose its notch S4 under the detent wheel |83, an action of the speed control cams |53 and |54 will take place. All additional rocking of the shaft 54 will incree se the displacement of the dire"iohal cam It?, but, owing to the fact that the rise 2||i on this cam has a large arcuate extent, this will not change the fact that the switch 295 remains closed. It will, however, further tighten the handle return torsion spring |18.

Such further rocking of the indexing cam 90 will cause its lower edge |43, laterally of the ari` cuate portion thereof, to displace 'the' roller |42 iurthor away from the center of the carri.` This,`

will rock the link |39 upon which the roller |42 is mounted to drive its upper end toward the shaft i4 a predetermined distance toward the front of the control casing, which" is clockwise viewed from the handle endof the casing. This contacts of the switches 25|! and 25|.

will apply a tightening to the coil spring 5| and Will Withdraw the upper end of the crank arm |45 from the linger |55 on the cam |53. The force of the spring |5| is sul'licient to cause the cams |53 and |54 to follow until the ringer |55 again engages the upper end of the crank |45. Such movement is sufficient to cause the rise 2H] on the cam |53 and the rise 2|3 on the cam |54 to close the switches 20|) and 25|. This will be evident as being the rst speed position indicated in Fig. 58.

In the foregoing displacement of the cams to their nrst speed position, the pin |52 rises from the bottom of the slot |51 in the arm connecting into the timing mechanism to the top thereof without displacing the sectorial gear in the escapement device. This is a valuable feature in the present arrangement, as will appear hereafter. y

Reference to Fig. 58 will show what heppens when the switches 205, 35| and 2GB are thus operated. There will be a circuit from the negative side of the battery through the line 432, the seat switch, the fuse and the lock to the movable Closure of the switch 260 will continue the circuit from the line 402 to the line 42D. This circuit cannot continue through the branch line 422 because both of the switches 368 and 374 are open until their coils are energized. However, the circuit can continu through the coil 295. thence by way of the line 42| be' ck to the line 455 and the positive side of the battery. This energiaation of the coil 235 will draw the core of the solenoid in, whi is represented in the wiring diagram by a ro lng lever that closes the contacts 3H and 3|! with each other, and at the same time opens the contacts 3091 and 3|!) from each other.

When the contacts 3| and 3|2 are thus closed, the second cam switch 25| becomes effective, because it continues from the line to 'the line 43d that leads through the foregoing sol switch contact to the line 4124 that connecL the lin'e 423 leads to the forward switch f2. thence by way of the line 425 to the coil of the relay 365, and thence to the line /li' and the positive side of the battery. This energization of the coil 365 pulls its armature 3536 up to break with the contacts 351 and to make with the contacts 368. It also closes the switch Fig. 59 shows in abbreviated iorrh what happens in the motor circuit when this solenoid switch 360 is thus actuated. The motor out .in series Iwith both sections 352 and 35S oi' the resistor so thatit operates at a slow rate ci speed, the current flow through the iield winding being in a direction tomobtain forward rotation of the motor. In Fig. 59, this may be assumed to be a current flow from left to right in the ileld winding 35|.

The actual detailed circuit corresponding to first speed forward can be based cn Fig. 58 by taking the line 45| from the negativo side of the battery. This will connect to the contacts ci. the energized solenoid switch 355, thence by the line 409 from the bottom to the top cf the field. winding 35|, thence by the line i-t3 to switch 36|, the contacts H2 of which are closed, and thence by way oi' the line 435 and through both resistors 353 and 352, through the motor and the line 400 back to the positive side ci the battery.

When the solenoid 360 closes the holding switch 369, a circuit is established in parallel with that established by the cam-actuated control switch `11'? :20|, which circuit is dependent `v.upon continued energization of the coil355. iSuch circuit extends Afrom the line 402 through 'the riirst cam-operated switch 200, the line 42.0, the branch Vline 422, the switch 3.69, the line 423, and thence, as before, through the forwardswitch 205, the line-425 and the vcoil 355. As long as thecoil 365,'therefore,

remains energized, and the switch'200 remains fthe crank arm |45 and the pin |50 a further `distance from 'their vstarting point. This applies additional torsion on the Aspring I I, and tends to .draw the cams |53 and |54 a ,further distance yaway fromV neutral. However, when this arnount'of action s'produced for these two foams, thepin |52 'is displaced in engagement with the upper end of the slot |51 of the connecting link |55 that .leads to the timing or escapement device.

torsion spring |5| is thencaused'to apply .an upward force to this arm |55. As shown in Figs. le Vand 19, this upward forcetends ktorock thesector .geare23'l to drive the'small gear 240. The small gear 2.40 acts rthrough ,the ratchet dog 244 to apply "force to the larger gear 243, which is in mesh with vthe `small :pinion 249 that has the yescapernent wheel l25| thereon.

At the start of the 'operating -of the truck, it fwas stated that the solenoid'294 -had its blocker element292 inthe .path `ofmovement of the stop 'element on the escapement lever.252. Previously described operations -to first speed `have caused energization of the solenoid and the withdrawal of the blocker292 from-the path :of .this .escapement lever. Therefore, `the'rotative effect applied tothe'escapement wheel 25| .can causea rocking of the escapement lever 2 52 through the interen- The -gagement of the pins 251 `and .258. The escape- -ment lever, by meansof the engagement of its slot -255 over the pin `282 .on the balance .wheel lever 253, causes the latter .lever .to rock. The balance wheel lever 258has its vpin..285 engaging in-theslot 287 to oscillatethebalance wheel 288. The speedat `which the escapementcaneperate is a function of the adjustment of the adjustment bar 211.0 Ythatdisplaces the pivot point vof the balance wheel lever 208. Consequently, the permitted speed of rotation of thegear train, ,and ultimately the speedat which lthe rvarm |156 may rise is .determined by the escapement mechanism whichis driven 'from vthe torsion vspring |5| within the Ycam |53.

As a result of the foregoing, the initial displacement of the crank arm and the pin |50 ofthe .spring |5|, occasioned by displacement of the -nism until the finger on the cam |53 4again engages the top of the lever |45 in the-new position of the latter.

Reference tothe wiring-diagram of Fig. 58will illustratethat in thesecondspeedposition the `'cam rise -2|0 lholds-the initial cam `switch 200 `on the cam |54 will close :the switch 203.

coil `A35,5.

closed. The .cam rise 2 I3 withdraws ,to permitreopening of the switch 20|, and the cam rise 2|| .In other words, in the second speed position, the switches 2,00 and 203 are closed, the other two cam switches being open 'The switch 205 `remains closed.

With the switch Y200 continuing closed, its `circuit to the solenoid coil ,29.5 can continue; and also its circuit through theline 422, the holding switch 369, the line 423, and thence to the vforward switch 205, and back by the line 425 to the vcoil `355, can remain energized, 2depending upon `continued closure 4of :the holding switch 3,69 vat the This will maintain the blocker 2,92 out .of the way ofthe escapement mechanism, ,buttitis independent of .c ontinuedclosure of the contacts 3|| and .3|2.

'In addition, the third cam-operatedswitch 203 carries the negative side of the battery from the line 4.02 to the line 4.3.2, whence it continues 4to -the coil 315 of rthe truck relay .352, ,andl thence by way of ,the line 400 back to the positive side of the battery.

The effect of this on the motor eld winding ,is

`indicated. in Fig. 60. The solenoid 362 .being ener- :gized shunts the smaller rresistor 3753 and leaves the Vlarger resistor :3,52 in series with the field. Consequently, the motor operates at Va somewhat faster speed than before.

This circuit may be traced indetail by `starting vfrom .the line .40| throughthecontacts 368-ofthe solenoid .360, the line 409, from bottom to top of the field winding,3.5|, the line'400, the contacts 312, the line 406, upwardly kthrough ,the contacts 382 of .the solenoid A363,-the line 4|0, the contacts 31.8 of the solenoid 362, the line 405, back-to the .upper yend of the resistor352, thencethrough that resistor `to thetmotor 350, .andby way ofthe lines 403 and 400 to the positive side of the'battery. `It -will be seen .thatthe effect, therefore, loffenergizing the solenoid'362 is to shuntthe resistor 353.

'If the. operator moves :the arm another notch on the 'indexing wheel, l.bringing the notch96 Y vthereof under the kdetent roller |03, there willbe -a similar additionaldisplacement of the cams |53 and .|54 regulated by the Atiming mechanism jin lprecisely the same rmanner aspreviouslydescribed in connection lwithftlie establishment of vrsecond 'speed forward. 'When the time determined by the setting of the escapement mechanism has elapsed, `the cams |53. and `|54 will have moved so Ythat the -switch i200 Aremains closed, the -switch 203 Aremains closed land the switch 204 vis .also closed. The ultimate effectof-this is shown in Fig. 61, which illustration shows that'thelarger resistor 352 is-now shunted,while the smaller re- -sistor 353 is in circuit. This produces a faster operation of the motor.

`The Vdetailso'fthis circuit can be obtained by again taking'FignB, following the negative side of the battery-through the line 40|, thefcontacts 368 of the rst relay 360, the line 409, the field `windirig||5| from bottom to top, the line 40,8, the

contacts 312 of the re1ay35|, the line l40,6, the small Yresistor 353, the line 405, the contacts 318 of the lrelay 352 the line 4|0, the contacts 383 of 'the relay 363, the line 4154 tothe motor v3 50, and

thence by lway of Ythe lines `403 Vand 400to the Vpositive side'of the battery. This circuit, too, is

dependent upon continued closure vof the holding switch 369 of the relay E0.

In order to establish fourth speed forward, the

actuating arm 10 is operated underanother notch so aste bring-thenotchz'l in the index plate-90 under the detent wheel |03. This produces further displacement of the cam roller |42 and hence further displacement of the crank arm |45 and the pin |50 to further tighten the torsion spring |5I. It again acts through the timing mechanism to produce an ultimate displacement of the cams |53 and |54 until the finger |55 on the cam |53 can again advance into reengagement with the upper end of the crank arm |45. The escapement mechanism in this operation determines the speed at which the cams |53 and |54 will follow the displacement of the arm.

When this position is obtained in the cams |53 and |54, the situation will be as indicated for fourth speed in the wiring diagram of Fig. 58. The switch 200 will remain closed, the switches and 203 will be opened and the switch 204 will be closed. The switch 200 will again maintain its holding circuit to the relay 360, dependent upon continued closure of the switch 369. It will also continue to hold the coil 295 energized so that the timing mechanism may operate. `Opening of the switch 203 releases the solenoid 362. Closure of the switch 204 establishes a circuit to the solenoid 363, from the line 402 as previously, through the line 433, to the coil 380 of the solenoid 360, and thence by the line 400 to the positive side of the battery. The effect of this is shown in Fig. 62. The solenoid 363 establishes a shunt circuit for both of the resistors 352 and 353.

Fig. 58 shows this circuit to be as follows: From the negative side of the battery through the line 40|, the contacts 368 of the relay 360, the line 409, from the bottom to the top of the field winding the line 408, the contacts 312 of the released relay 36|, the line 406, the contacts 311 o! the relay 362, the line 4|0, the contacts 383 of the relay 363, the line 404 back to the motor 350, and thence by way of the lines 403 and 400 to the positive side of the battery.

If the operator desires to slow the truck from a higher speed to a lower speed, without changing direction, or to return it to neutral position, he merely returns the lever 10 back to the chosen speed or to the neutral. The cams will immediately return from an advanced to a retarded position that does not involve a change of direction of the motor without having any actuation of the time delay mechanism, because the ratchet 24|, 244 is designed to permit such return movement.

However, once the neutral position has been attained again and the operator moves the handle 10 beyond neutral in an opposite direction from a position formerly occupied, the timing mechanism will again come into effect between ilrst and fourth speeds. This is true because, regardless of the direction obtained by the cam |61, the speed controlling cams |53 and |54 always are displaced in the same direction with respect to the upper shaft 64. This is true because the indexing cam 90 can displace the cam roller |42 and the linkage only outwardly or inwardly.

In order to operate in reverse, the operator moves the actuating arm 10 to the first notch to the opposite side of the neutral notch 9|, which is the notch 93. As in the previously described manner, this will cause the cam |61 to move clockwise, viewed from the actuating arm end of the shaft 64, to displace the rise 2 6 under the switch 202 and to close the same, leaving the switch 205 open. This pre-disposes the circuit for operation of the motor in the chosen reverse direction. When thereafter iirst speed position of the lever in reverse is obtained, the cam-operated switches will assume the same positions they occupied for first speed forward. For example, when the switches 200 and 20| are closed, there will again be a circuit from the negative side of the battery through the line 402, the switch 209, the coil 295 and the line 42| back to the positive side of the battery, and also a connection through the line 422 that leads to the two now open switches 369 and 314. However, the switch 20| will establish a circuit from the line 402 through the line 430, and the switch 3| 3|2 closed by energization of the coil 295, and the line 424 to the line 423. This latter line now connects through the reverse switch 202 to the line 42-6 that leads to the coil 310 of the reverse directional relay 36|, and thence by the line 400 back to the positive side of the battery. Consideration of the control circuits will show that all of the speed cam positions will establish exactly the same combinations of the relays 36|, 352 and 363 that were previously made with the relays 360, 362 and 363. In other words, the only difference is that the relay 36| is energized for reverse; Whereas the relay 360 is energized for forward speeds.

Energization of the relay 36|, of course, closes the holding switch 314 instead of the holding switch 369.

The first speed reverse circuit is typical and is shown in Fig. 63 in brief. It will be seen that the closure of the solenoid 36| puts both oi' the resistors 352 and 353 in circuit, but the connections lead oppositely through the field winding to change the direction of the motor, This circuit may be traced in detail in Fig, 58 by taking the line 46| from the negative side of the battery to the contacts 313 of the relay 36|, the line 40B, entering the top of the eld winding 35|, the line 409 from the bottom thereof, the contacts 361 of the relay 366, the line 4016, the two resistors 353 and 352, the motor 350, and the lines 403 and 466 to the positive side of the battery. Thus in the reverse circuits the current previously discussed moves from top to bottom of the eld winding; whereas before it moved from bottom to top. This change is produced by energizing the relay 36| with the relay 360 deenergized in place of the opposite conditions.

If the operator, while moving rapidly in one direction, suddenly pulls the lever backwardly to position the control to cause the motor to operate in the other direction, a delay is interposed to prevent energizing the motor for reverse direction until it has slowed down and at least substantially stops.

This is obtained in the following manner: When the handle is neutralized, all of the camoperated switches are open, and, as a result, all of the relays 360 through 363 at the truck are released to deenergize the motor 350. It has already been described that neither of the two relay coils 365 and 310 of the relays 360 and 36| can be energized solely by the closure 0f the cam-operated switch 203, because the circuit established thereby is dependent upon closure of the holding switches 369 and 310 that are closed only after the coils themselves are energized. Hence the function of the second cam-operated switch 26| is to establish an energizing circuit for the one or the other of these two coils, which can be done safely at low speed operation, and which energizing circuit is open at all speeds above rst speed operation. But this energizing i circuit through the switch 20| is dependent upon closure of the contacts 3| and 3 2 of the solenoid F21 fswitch mechanismaassociate'diwithithe timingv 'de- Nice.

*#The second coilrzeiof thisisolenoid is abucking fcil ithat, whenfenergized, L reducesA the powerof the main 'coil`2 95 to azva'luestooilowlfto` overcome l'thevspringS and: pulltheswitchblade vover .to 'close the-fcontacts 3||fzand3|:2. Offcourse, when "both coils 2:55 andZaredeenergizedthe spring @causesl thercontacts' 3109 :andi 3 |10 to' be closed.

lWhenr the handlel then: ismove'd ."from 1.a high "speed positionbackftoneutral, the coil1'295is de- .energized so that the switch. may L drop .back to r 'close'` the contacts 3&9 and 3 I 0 and` to :Opern the '.contacts3ll and3|21in the initiating circuit. fAll fthe'frelay switches3360 lthroug'h 363 "arerelease'd, If the *handle "lil lis' continued from neutral-:into an foppositei speed position, it i must actuate the switch 20| to closed position and must .energize 'the fcoil F295 infa manner fto pull the solenoid v switchf contacts 3 I and@ 2 .closed .before-either "of'fthacoilsb vand 355|.'can'beenergized. :And if neither .is energized then: the subsequentrelease-of the switch-.20 lto establish ra second; third for fourthfspee'dposition willbeineective. (The fonly connectiony from .the negative side i'of Lthe i 'batteryinto the truckfcontrol is by v'way vofLthe line 40 and .this 'line lis :broken munless one for the `other 'of-the coils i165 ori-31e isfenergized iWhen thehandle is rapidlyfreturned tofneutral vfromf aniadvanced speed Lpo'siti'on, Athemotcri358 is "drivenby the truck andJacts as f-'a generator. With Ithe control in the.' position y previously ide- A`scribed, the motori-350,v acting .asa-generator, de- Flivers current 'throughaa circuit :includingthe lline 'i4-35, the contacts yI3 |19 and L3 U9," the coil 2%,

theline 42|,the'line vlISOI) 4randithe'line"' back 'to the'motor. The-motordriven .at substantial 'speedsf by l the truck 'generates vsufii-cient :current Afto energize .the Abucking coil v'1235361.adequately.ilto prevent the lcoil 295 fromfpulling thelrelayfiswitch foverto closefthe contacts 3H and23|='2. This condition will obtain until"themotor'haseslowed down atleast 'a predeterminedxamount rThe core of the 1 solenoid 294 remains released, the `ltiming mechanism remains blocked, :and the :star-ting circuit r requiring.` closure i' of fthe contacts 3'I| and i3 I2 rcannoi'fbe energized. The op'erator is thus required to 'neutralize "the 'handlefrom "driving in one-direction; and overtravelxnot -beyond'the Lrst` speed in the other directiomiwaiting' then until .thel motor slows downrsuiliciently I'to letr .the 'solenoid' act ito iestablishzthe fstarting circuit fortravel .in the-oppositedirection.

'fThe'foot controlicrank |;|3i.is:capab1eiof prolviding :accelerationl in either :selected f direction, Y

androf neutralizing. Asfpreviously indicated,athe indexing plate L 9 0 Yhas ar-cami protrusion f|a331that holds the :connection I3 I v.of f the:footlatcnlever 28faway1ircm the,;cam--rol1er- |42 whenthe .plate .9|| is in-.neutral position. AHowever, when the'V plate-.Shas been ymoved in either direction'ifar Yenough to selectfeitheriorward.orreversey the -Aconnecting jportion |3| '.can l engage .fbehind the .'camroller |42. Thereafter, whentth'efoot crank I|3 lis '.roicked to .rock the shaft l 61 clockwise, .'-viewedirom :the handle endjthelatch lever |28, 'aurged overthe :roller |42 bythe lspring |34,iwill draw the cam roller |42Youtwardlyfinthe'fsame fdirection it 4is "driven "by further advancing of *the indexingplate 90 'away fromvneutralposiftion. This will obtain the same action'ofthe 'speedcontrol cams |53 fand |54 thatis obtained lby the manual'op'eration of the handle 'I`||,"but *the indexing disc 43D Awill not "move norwill the `shaft Bl'move. "Thespring Ml, acting upon the leverA |39,11opposessuchidisplacementrofithe. lever |3|,.T so thatrelease Vof the iiootccrankl` I I3w1lrbe Afollowed.by-return of the arm |39.;backto..its initial .position-[determined by. thelindexinggcam. 5 Of course,1.this1wll be followedtby` returnlotthe speed ...control cams .|53 `and LI54. .By .this 'far- Vrangement;` :the operator; mayimanually; selectthe direction of "travel, and :thereafter :obtain his speedrbyfoot operation.

The foot operation further .may :completely :neutralize 1 the vfcontrol, regardless of its .having been positioned in some operating speed J by .1a

manual .operationof :the member v'I(|, `and conse- :quent .displacement ofithe indexing. cam 90; and ^operation V.of the detent |03. If the :operator :moves :the crank :arm '||3 `counterclockwise, vviewed'from thehan'dle end tofthe casing,heiwll :L move -the 1 detentirelease arm 23 upwardly. At .za jpointhigh 'in the' counterclockwise.movement ofathetcrankll, the pin |24'will.have.'so;sli"d throughzthe opening; |09.. on they ledge lsiofzthe Idetentarm |04 that..theftop..ofthe loop'portion -zof :.theLlever .|23 :.willengage .the ledge I |.08::sand `cause a; rocking of the :memberl to'remove 25 the'zwheel |D3ifrom its notch in .'theindexing vplate 9). Whenlthisoccurs, thereturnlspring `mechanism,.built:around'the coil spring |18,.will irmnediately'return the shaft'f64 toits neutralposition, :followed "by neutralizing `of Vall-of lthe fm switches. As soon asithe .foot crank |3f.is;fre

` leased; thedetent ||l3y will return.

'Thelostmotion connection providedbythe pin engaging in the slot v|2I assures that Ia mere i .releaseof Vthe footipedalfsuiciently far'to. cause 5"ithec'onne'ction I3I '0n-the latching lever |28` to 'engage overit'he cam roller |42 Willfnot atthe Asame itime releaseltllev detentmeans.

'It'hasz previously been' noted that the time delay mechanism doesnotfoperate in"'first `speed ifforwardvor rreverse. .This provisionis made so that the .operator may make quick changesfin fdirectionof Lthetruck, atlow speeds, in order torwarp the truck into 'a small space. Sudden reversals of -direction of the motor at low speeds "aref notV harmful, and the motor, whenl driven by the 'Struck under such circumstances, does not rigenerate enough'current to operate Ythe holding fcoil J2'96toprevent the solenoid from pllingthe fswitcnin to close the kcontacts 3| I an'd"3|2.

It"-will"be vseen -that the control mechanism givesa vverydu'll and complete control forthe "cperationofa motive means, in several'speeds forward vor backward; andprovides' a control that n'is particularly valuable in connection with A"'truclcs,fsuchas are used in industrial capacities I-as l*within factories, railroad stations, land the like. It is extraordinarily compact, and in `fact Y the 'casing 'illustrated is approximately nine vinches tall fby five inches wide by five inches "deep vIts many desrablefeatures `appear'from --the "foregoing vdescription. While the over-all control s'particularly valuable for reasons indi- /eated,it1will of coursef'be understood that many oflthe 'component r'features are capablevof more (mfgeneral useyandisuchl general use is intended to be eneompassedwhere possible by the language *of vthe claims to'iollow.

yWhat is claimed is: ,n 1l. in -a mechanism of `the kind describekrfaJ i shaftpa crankarmsupported on the -sha'ft for .movement'about the-shaftaxis, a drivable 'member supported on the shaft for movement `about theaxis, fa spring between the crank arm and thevdrivable member for 'applying force to the "memberwhenthef'armf is moved; urging the member to move in the same direction, an escapement mechanism, means connecting the escapement mechanism to the drivable member to retard movement thereof to a predetermined speed regardless of the speed of displacement of the arm, said connecting means including a lost motion device providing a predetermined amount of movement of the drivable member free of the escapement mechanism, upon initial movement of the crank arm.

2. In a speed changing device for a multi-speed motor or the like, an actuator movable to a plurality of positions, an actuatable device movable to corresponding positions, yieldable force means interconnecting the actuator and actuatable device, switch means operated by said actuatable device in its several positions, and time delay means connected with the actuator and the actuatable device to cause the actuatable device to follow movements of the actuator to corresponding positions, only after time delay, a second actuator, means connecting the second actuator with the yieldable force means, and means to render said connection ineffective in predetermined positions of the first named actuator.

3. In a speed changing device for a multispeed motor or the like, an actuator movable to a plurality of positions, an actuatable device movable to corresponding positions, yieldable force means interconnecting the actuator and actuatable device, switch means operated by said actuatable device in its several positions, and time delay means connected with the actuator and the actuatable device to cause the actuatable device to follow movements of the actuator to corresponding positions, only after time delay, and means rendering the time delay means ineffective between predetermined positions of the actuator and actuatable device.

4. In a speed changing device, a multi-speed motor, an actuator movable to a plurality of positions corresponding to a plurality of speeds of the motor, an actuatable device movable to corresponding positions, yieldable force means interconnecting the actuator and actuatable device,`

switch means operated by said actuatable device in its several positions, and time delay means connected with the actuator and the actuatable device to cause the actuatable device to follow movements of the actuator to corresponding poi sitions, only after time delay, and means rendering the time delay means ineffective between predetermined positions of the actuator and actuatable device, said predetermined positions corresponding to low speeds of the motor, the time delay means being effective in changing to high speeds.

5. In a control for a. multi-speed motor, an actuator movable from a starting position through successive operating positions, an actuatable device movable to corresponding positions, low to high successive speed regulating switches operated by the actuatable device, connections between the actuator and actuatable device to cause the actuatable device to move with the actuator from starting position to the first operating position, and time delay mechanism to cause the actuatable device to move to a higher speed position beyond said iirst position only after predetermined time, regardless of the speed of movement of the actuator to a corresponding position.

6. In a control for a reversible multi-speed motor, an actuator movable from a starting position through successive operating positions, an

actuatable device movable to corresponding positions, low to high successive speed regulating switches operated by the actuatable device, connections between the actuator and actuatable device to cause the actuatable device to move with the actuator from starting position to the nrst operating position, and time delay mechanism to cause the actuatable device to move to a higher speed position beyond said first position only after predetermined time, regardless of the speed of movement of the actuator to a corresponding position, and the actuator being oppositely movable in like manner for reverse operation, forward switch means operated by the movement of the actuator in its first named direction, and reverse switch means operated by the movement of the actuator in its reverse direction.

7. In a mechanism of the kind described, a shaft, a crank arm supported on the shaft for movement about the shaft axis, a drivable member supported on the shaft for movement about the axis, a spring between the crank arm and the drivable member for applying force to the member when the arm is moved, urging the member to move in the same direction, an escapement mechanism, means connecting the escapement mechanism to the drivable member to retard movement thereof to a predetermined speed regardless of the speed of displacement of the arm, and means operated by angular displacement of the shaft to move the crank arm.

8. In a mechanism of the kind described, a. shaft, a crank arm supported on the shaft for movement about the shaft axis, a drivable member supported on the shaft for movement about the axis, a spring between the crank arm and the drivable member for applying force to the member when the arm is moved, urging the member to move in the same direction, an escapement mechanism, means connecting the escapement mechanism to the drivable member to retard movement thereof to a predetermined speed regardless of the speed of displacement of the arm, means operated by angular displacement of the shaft to move the crank arm, and detaining means yieldably maintaining the shaft in positions to which it is displaced.

9. In a mechanism of the kind described, a shaft, a crank arm supported on the sha-ft for movement about the shaft axis, a drivable member supported on the shaft for movement about the axis, a spring between the crank arm and the drivable member for applying force to the member when the arm is moved, urging the member to move in the same direction, an escapement mechanismy means connecting the escapement mechanism to the drivable member to retard movement thereof to a predetermined speed regardless of the speed of displacement of the arm, means operated by angular displacement of the shaft to move the crank arm, detaining means yieldably maintaining the shaft in positions to which it is displaced, and return means urging the shaft back to a starting position.

1G. In a mechanism of the kind described, a shaft, a crank arm supported on the shaft for movement about the shaft axis, a drivable member supported on the shaft for movement about the axis, a spring between the crank arm and the drivable member for applying force to the member when the arm is moved, urging the member to move in the same direction, an escapement mechanism, means connecting the escapement mechanism to the drivable member to retard 

